Manufacturing Bits: Nov. 26

Arctic Neutrinos From Space
Technische Universitaet Muenchen (TUM) has observed high-energy neutrinos stemming from outside the solar system, an event that could provide some clues about the universe. Researchers observed the sub-atomic particles at IceCube, a huge neutrino detector in Antarctica. TUM has observed 28 neutrinos that most likely came from cosmic objects.

The IceCube observatory is run by an international consortium under the direction of the University of Wisconsin at Madison. Completed in 2010, IceCube is melted into the permafrost of the South Pole. At one cubic kilometer in size, it is the largest neutrino detector in the world. Some 86 vertical wire ropes with a total of 5,160 optical sensors were sunk 1450 to 2450 meters into the ice.

IceCube observatory in Antarktica – Photo: Emanuel Jacobi/NSF

A neutrino is an electrically neutral particle. Billions of neutrinos pass through the Earth’s surface each second. The majority of neutrinos decay within the sun or Earth’s atmosphere.

Neutrinos that come from outside of the solar system are rare. In this case, they offer clues to the cosmic objects where they come from. They could stem from supernovas, black holes, pulsars, active galactic cores and other extragalactic phenomena. “These are the first indications of neutrinos from outside our solar system,” says TUM physicist Professor Elisa Resconi, on TUM’s Web site. “These events can be explained neither by causes like atmospheric neutrinos, nor by other high-energy events like muons created in the Earth’s atmosphere during interactions with cosmic rays.”

The first robot resembles a copter drone. Equipped with eight propellers, the robot is capable of flying at 15 mph for up to 20 minutes at a time. It can be equipped with a conventional visible light or thermal imaging camera.

The second robot looks like a small airplane, which can fly up to 50 mph for more than an hour. Both robots will help study the Peruvian cloud forest, which grows on the slopes of the Andes Mountains. This remote spot is a difficult place to reach and researchers know little about the area.

Source: Wake Forest University

In such regions, scientists collect data using remote satellite sensing or manually from the ground. “While there is satellite data on temperature and thermal distribution in the Amazon going back to the early 1970s, it doesn’t provide the resolution necessary to build the detailed models we need,” said Miles Silman, a biology professor and director of the Center for Energy, Environment and Sustainability (CEES) at Wake Forest, on the university’s Web site. “The only other alternative is to rent out a helicopter, which is far too expensive for any kind of continuous observation.”

Max Messinger, a biology graduate student, said the drones will gather thermal data down to a few centimeters and visible light data down to the sub-centimeter level. “This will allow us for the first time to see how individual canopies are functioning on a landscape level to fix carbon and release oxygen and water,” Messinger said. “Once we build a better understanding of why the forest is behaving in a certain way we can start making decisions about how do we conserve this region and ensure that it continues to function.”

Terahertz Vacuum Tubes
For years, researchers have been trying to develop terahertz-based devices. But device physics has prevented traditional solid-state electronics from operating at the terahertz scale.

The sub-millimeter wave, or terahertz, falls between the frequencies of 0.3- and 3-terahertz. For some time, DARPA has been developing terahertz devices within its so-called Terahertz Electronics (THz) program.

In a major breakthrough, DARPA has now demonstrated a 0.85 terahertz power amplifier using a micro-machined vacuum tube. DARPA-funded researchers at Northrop Grumman Electronic Systems built the 1 centimeter-wide traveling wave vacuum tube.

Geared for military applications, these devices could be used in communications, radar and spectroscopy imaging. These technologies could enable wireless networks exceeding 100-gigabits per second. Other applications include plans to insert the THz-class amplifier into a demonstration of DARPA’s Video Synthetic Aperture Radar (ViSAR). ViSAR seeks to build a sensor system for aerial platforms that peers through clouds to provide high-resolution, full-motion video for engaging moving ground targets in all weather conditions.

“Vacuum tubes bring back visions of antique electronics, but these are not your grandparents’ TV sets,” said Dev Palmer, DARPA program manager, on the agency’s Web site. “Further research and development in this field will help unlock applications for our military in this historically difficult to access part of the spectrum.”